Internal Pressurization Bubble Testing System for ASTM F2096

Description of this ASTM F2096 Bubble Leak Testing System

Internal Pressurization Bubble Testing System for ASTM F2096

This Internal Pressurization Tank System is designed to Detect Gross Leaks in Packaging by Internal Pressurization of test samples – Also known as a “Bubble Test”. It is built to meet or exceed the specifications set forth in the testing procedure ASTM F2096 – 11. The Sensitivity of this test method is 250 micro meters (0.010 in) hole diameter. The probability of bubble detection emitting from a hole that is 250 micro meters (0.010 in) is 81%. Keep in mind that this System has not been evaluated for porous materials. The examination specimen for this testing procedure can be, including, but not limited to: Pouches, Trays, Boxes, Bottles, Bags, Pockets, Purses, Receptacles, Sacks, Plates, Jars, Jugs, Vials or anything else that can be punctured by the testing probe, submersed under water, and pressurized with air.

The advantages of this test method are that this is a very practical leak test that delivers immense value fast by giving you the test results you need within 30 seconds or less. Another advantage of Bubble testing your packages is that the leak can be identified and located rapidly allowing you to spot patterns or inconsistencies during your testing. This System is extremely useful in a laboratory environment where uncommon or diversely shaped and sized specimen are tested. Moreover, long or oddly shaped packages can be easily tested with this system too. This testing methodology is perhaps the simplest way to evaluate package integrity of sealed packages where contamination free, sterile, or air-tight seal is of uttermost importance. Finally, no special conditioning or sample preparation is required - meaning that you can complete your package integrity test within a very short timeframe.

This Bubble Leak Testing System is specifically built for the ASTM F2096 – 11 Testing Procedure, it is therefore advisable for you to obtain a copy of the appropriate Document. If you do not have it, a copy can be purchased directly from ASTM by clicking on the link below:

Before you begin, it is advisable, but not necessary to plumb the drain valve of your tank into the main drain for reasons allowing you to empty the water out of the tank after use. To properly operate this System, the Drain Valve must be closed first. After the Drain valve has been closed, fill the Clear Acrylic Tank with water. Make sure that the water level reaches beyond the lids and that the bottom of these lids is fully submerged under a minimum of 1 inch (25.4mm) of water.

Detect Gross Leaks in Packaging by Internal Pressurization

Prepare your testing specimen first by visually inspecting and cleaning it. Although this step is not necessary, sometimes your samples may need a little bit of cleaning in order to prevent sullying your water in the acrylic tank. Insert your static probe into your specimen. Use Tape, O-Ring, Pad, Rubber Disk as a septum over the puncture location in order to seal the puncture properly so that no bubbles emit at the insertion location which may invalidate your test. With the static probe inside your test sample, open the acrylic lid of your System and place the test sample under water. Close the lid and apply pressure to your specimen.

Keep in mind that the pressure can be applied to your specimen before it is submerged. However, in that case, it will be a bit more difficult to submerge it due to air presence in your specimen which will buoy your sample upwards.

While your sample is fully under water, and your set pressure is applied to your specimen, carefully observe the perimeter of your package, seal, etc… for bubble emission. You have to be focused and clinical with your observations because this test is subjective where not being fully observant during your test may negatively impact your final test results.

One way to increase the sensitivity of this test is to increase the pressure applied to your sample. However, excessive pressurization may damage your specimen and cause you to misinterpret your overall results.

As your sample is pressurized and expanded, thoroughly inspect one side of your package and specifically look for bubbles. How long you look for bubbles depends on your package type. After you have thoroughly inspected one side of your pouch specimen, rotate your pouch by 180 degrees and repeat looking for bubble emissions once again.

If your package is cube shaped, you may have to test all six sides of your package. An adequate test procedure and sampling method must be established in order to have the most accurate test reporting system. One way to establish a good test procedure is to create a leaking specimen (control sample or known leaker) and then bubble leak test your known leaker for detection confirmation.

Lastly, it is very important that you fully understand the advantages and limitations of your testing procedures. Your test sensitivity, which is defined by the probability to correctly detect a defect is 20%, 51%, 81%, and 95% for defect size of 50μm,125μm, 250μm, and 350μm respectively at a pressure of 5 inches of Water (0.2 PSI).

A more comprehensively written document by the ASTM which describes the process we talked about in a much more eloquent way is available for purchase by clicking on the link below:

If you are still reading this, then we would like to thank you for taking the time to read this write up all the way through. It took us quite some time to write this for you. Please don’t hesitate to contact us if you have any further questions, comments, or concerns regarding this article.